|Publication number||US6291875 B1|
|Application number||US 09/322,381|
|Publication date||Sep 18, 2001|
|Filing date||May 28, 1999|
|Priority date||Jun 24, 1998|
|Publication number||09322381, 322381, US 6291875 B1, US 6291875B1, US-B1-6291875, US6291875 B1, US6291875B1|
|Inventors||William A. Clark, Thor N. Juneau, Allen W. Roessig, Mark A. Lemkin|
|Original Assignee||Analog Devices Imi, Inc.|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (31), Non-Patent Citations (4), Referenced by (92), Classifications (16), Legal Events (6)|
|External Links: USPTO, USPTO Assignment, Espacenet|
This application claims the benefit of U.S. Provisional Application No. 60/090,519 filed Jun. 24, 1998.
This invention was made with Government support under NAS5-97227 and DMI 97-60647 awarded by the National Aeronautics and Space Administration (NASA) and the National Science Foundation, respectively. The Government has certain rights in the invention.
This invention relates generally to microfabricated devices, and more particularly to three-dimensional devices fabricated with high vertical to horizontal aspect ratios. This invention results in high-aspect-ratio devices that may be fabricated with integrated circuitry on the same substrate using conventional microfabrication techniques.
MicroElectroMechanical Systems (MEMS) combine mechanical structures and microelectronic circuits to create integrated devices. MEMS have many useful applications such as microsensors and microactuators. Examples of microsensors include inertial instruments such as accelerometers and gyroscopes, detectors for gasses such as carbon-monoxide, and pressure sensors. Examples of microactuators include optical mirrors used for video displays, switching arrays, and disk-drive head actuators used for increasing track density.
Many MEMS-based devices utilize electrical circuits combined with air-gap capacitors to sense motion, or to apply electrostatic forces to a movable structure. Air-gap capacitors are often formed between sets of capacitor plates anchored to a substrate interleaved with plates attached to a movable structure. The performance of many capacitive-based MEMS improves as: 1) the overlap area of capacitor plates increases, 2) the distance between the stationary and movable capacitor plates decreases, 3) the compliance of the structure varies dramatically in different directions, and 4) the mass of the structure increases. Each of these performance issues is enhanced using high-aspect-ratio semiconductor technologies, wherein thickness or depth of fabricated structures is much larger than small lateral dimensions such as width of flexible beams and gaps between capacitor plates.
Electrical interfaces for capacitive-based MEMS require electrically isolated nodes spanned by one or more variable capacitors such as an air-gap capacitor. Thus, capacitive interfaces using capacitors formed between structural elements require electrical isolation between these structural elements.
The performance of devices such as accelerometers and gyroscopes may benefit from combining high-aspect-ratio structures with circuits integrated in the same substrate. Hence, a high-aspect-ratio structure etched into a single-crystal silicon substrate that also contains integrated circuits is of particular interest. Of even greater interest is a process sequence that yields structures and circuits in the same substrate but does not significantly alter complex and expensive circuit fabrication processes. Such a process sequence enables cost-effective manufacture of devices comprising integrated circuits and structures on a single substrate.
For improved performance, an integrated MEMS process should address three issues. First, the structural elements should be formed by a high-aspect-ratio process. Second, fabrication of mechanical structures should have a minimal impact on fabrication of associated circuitry on the same substrate. Third, structural elements should be electrically isolated from one another, the substrate, and circuit elements except where interconnection is desired.
In one aspect, the invention is directed to a microfabricated device. The device includes a substrate that is etched to define mechanical structures that are anchored laterally to the remainder of the substrate. Electrical isolation where mechanical structures are attached to the substrate is provided by trenches etched in the substrate that are subsequently lined with an insulating material.
Circuit elements may be formed in the substrate material. Conducting material deposited over isolating trenches may be used to interconnect electrically isolated circuit and structural elements. The insulating lining deposited in the trenches may fill the trenches or the lining may be filled with a second material that is not necessarily insulating. The substrate may also include a device layer in which one or more structures and electrical circuits are formed, a handle layer, and a sacrificial layer between the device and handle layers. A portion of the sacrificial layer may be removed to free the structures from the substrate. The sacrificial layer may include silicon dioxide, the substrate or device layer may include single-crystal or epitaxial silicon, the isolation material may include a silicon nitride, and the trench fill material may include polycrystalline silicon.
Performance of devices fabricated in accordance with the invention is improved due to the proximity of interface circuitry built into the same substrate as the microstructures. Performance of microstructures is improved due to the high-aspect-ratio fabrication that yields larger mass, air-gap capacitors with larger sensitivity, and improved suppression of undesired deflections-particularly deflections out of the plane of the substrate. The invention is compatible with existing microfabrication techniques and is compatible with established integrated circuit fabrication processes.
For a better understanding of the nature and objects of the invention, reference should be made to the following detailed description taken in conjunction with the accompanying drawings, in which:
FIG. 1a is a plan-view and FIG. 1b is a cross-sectional view of the starting material and the region of the substrate in which trenches will be formed.
FIG. 2a is a plan-view and FIG. 2b is a cross-sectional view of a trench after the first deep-RIE etch.
FIG. 3a is a plan-view and FIG. 3b is a cross-sectional view of a trench after the first trench is filled.
FIG. 4a is a plan-view and FIG. 4b is a cross-sectional view of a trench after trench-fill material is removed from the surface of the wafer.
FIG. 5a is a plan-view and FIG. 5b is a cross-sectional view of a trench after fabrication of integrated electronics.
FIG. 6a is a plan-view and FIG. 6b is a cross-sectional view of a trench and a simple mechanical structure defined by the second deep-etch.
FIG. 7a is a plan-view and FIG. 7b is a cross-sectional view of a trench and a simple mechanical structure after removal of sacrificial material.
FIG. 8 is a perspective cut-away view of the released mechanical structure shown in FIG. 7.
FIG. 9 is a perspective cut-away view of a device that has multiple electrically isolated nodes on a single mechanical structural element.
FIG. 10 is a perspective cut-away view of one region in which stringers may form.
FIG. 11a is a plan-view and FIG. 11b,c are cross-sectional views of a trench with a condyle.
FIG. 12a is a plan-view and FIG. 12b,c are cross-sectional views of a trench with a condyle during deposition of insulating material and before pinching-off of the trench occurs.
FIG. 13a is a plan-view and FIG. 13b,c are cross-sectional views of a trench with a condyle during deposition of insulating material after pinching-off of the trench, but before pinching-off of the condyle occurs.
FIG. 14a is a plan-view and FIG. 14b,c are cross-sectional views of a trench with a condyle after deposition of insulating material and after pinching-off of both the trench and the condyle.
FIG. 15a-f is a series of plan views of trenches terminated with different-shaped condyles.
FIG. 16 is a perspective cut-away view of the released mechanical structure shown in FIG. 7 with a diamond-shaped condyle.
FIG. 17 is a plan view of a substantially planar device with multiple mechanical structures and multiple interconnects integrated with circuitry.
FIG. 18 is a plan view of a substantially planar device with multiple mechanical structures, nubbins, and geometric design rules.
FIG. 19 is a plan view of a substantially planar device with multiple mechanical structures, without nubbins, and with geometric design rules.
FIG. 20a is a plan-view and FIG. 20b is a cross-sectional view of a trench and a simple mechanical structure after removal of a region of the handle-wafer underneath the region of the mechanical structure.
FIG. 21a is a plan-view and FIG. 21b is a cross-sectional view of a trench and a simple mechanical structure after removal of sacrificial material.
Fabrication of devices in accordance with the present invention, as illustrated in FIG. 8, comprises three basic steps: formation of a set of insulating trenches 20 a-c, formation of interconnection 31 and 32, and the formation of structures 21. FIG. 1 through FIG. 7 illustrate these fabrication steps.
Referring to FIG. 1, the starting material 10 may comprise, in one embodiment, a bonded wafer structure having a number of layers including: a handle wafer 10 c, a sacrificial material 10 b, and a conductive device layer 10 a. While different materials may be used, the handle wafer may be single-crystal silicon, quartz, or glass; the sacrificial layer may be silicon dioxide; and the device layer may be single-crystal silicon. Alternatively, the device layer may be single-crystal silicon with a surface coating of epitaxial single-crystal silicon tailored for the fabrication of integrated circuitry. When the device layer contains an epitaxial silicon layer, dopants may be selectively introduced (through implantation or diffusion, for example) into regions of the epitaxial layer to enhance conduction from the surface of the device layer to the silicon on which the epitaxy is deposited. In addition, a material such as silicon dioxide may be deposited or grown over the surface of the device layer to protect the device layer from damage during trench formation and filling.
A first trench etch cuts through the device layer at least as deep as the sacrificial material 10 b. As shown in FIG. 2, the first trench etch results in trench 11 and may be performed using a reactive-ion etch (RIE), for example. Trench 11 is then lined with an insulating material 12, such as Low-Pressure Chemical-Vapor Deposition (LPCVD) silicon nitride, shown in FIG. 3. The insulating material 12 may be used to completely fill the trench 11 or additional filler materials, such as silicon dioxide or polysilicon, may be used to complete the fill of trench 11. Referring to FIG. 4, once the trench 11 has been filled, the trench fill material 12 is removed from the surface of the wafer to reveal the surface of the substrate 10 a. Removal of trench-fill material 12 from the wafer surface may be achieved using dry- or wet-etching, grinding, or chemical-mechanical polishing, for example. This completes the formation of the filled insulation trenches 20. Note that a mechanical device may have a plurality of insulation trenches 20, as described below.
Referring to FIG. 5, the formation of circuit elements follows the formation of the insulation trenches 20. Circuit formation may be accomplished using any number of well known semiconductor circuit fabrication processes, such as CMOS, that will result in electronic circuit elements, such as transistors, and electrical interconnection among circuit elements. In addition, circuit formation may result in one or more conductors 31 that connect to the substrate material by contacts 32. The conductors 31 and contacts 32 may permit electrical connection among structures 21 and electrical circuits 30. Electrical circuits may be used for measurement of capacitance (often called sense-capacitance) between isolated mechanical structures to yield a quantity representative of distance between the mechanical structures, for example. Electrical circuits may also be used to apply voltages to isolated mechanical structures to generate electrostatic forces. Other uses of electrical circuits include, but are not limited to: calculating or signal processing of quantities based on measurements of sense-capacitance, sustaining oscillation of a mechanical structure, measurement of changes in a piezoresistor which may be formed in the device layer, and measurement of current flow due to electron-tunneling between isolated mechanical structures.
Mechanical structures are defined with a second etch. Referring to FIG. 6, a deep etch, which may be a deep RIE for example, removes excess material 10 a to reveal sacrificial material 10 b. Removal of excess material 10 a leaves open regions 25 which may define mechanical structures such as comb-fingers 21 e,f,g, movable proof-masses 21 c, or suspensions 21 d as shown in FIG. 17, for example. Note that sacrificial material 10 b may serve as an etch-stop layer for the second etch. The removal of excess material 10 a not only defines mechanical structures but also provides a majority of required electrical isolation between separate mechanical structures. Additional isolation is provided by isolation trenches 20 and by removal of sacrificial material 10 b as shown in FIG. 7. Sacrificial material 10 b may be removed with a wet-release process. When the sacrificial material 10 b is silicon dioxide any of a number of well known etching chemistries, including hydrofluoric acid, may be used to remove sacrificial material under structures 21 as well as remove sacrificial material exposed by open regions 25. In addition to providing increased electrical isolation, removing sacrificial material under structures 21 leaves open areas 26, mechanically freeing structures from the handle wafer. A perspective view of a very simple microfabricated device is shown in FIG. 8.
The process described above also provides for fabrication of structural elements that comprise multiple electrical nodes. FIG. 9 shows an example of a single structural element that contains multiple electrical nodes. In a unique feature of the present invention, two nodes may be electrically isolated from one another by refilled trenches 20 c. The structure is electrically isolated from and mechanically anchored to the substrate by refilled trench 20 a. Note refilled trenches 20 c are not mechanically attached to the underlying substrate due to the nature of the process sequence, thereby enabling movement of released mechanical structures with respect to the substrate.
Because of restrictions of processing technology, including RIE, a potential exists for electrical conduction between mechanical structures intended to be isolated. One method by which electrical conduction may occur is through conductive “stringers” 28 located along the wall of the trench. A stringer is defined as undesirable material left behind after etching. An example of a stringer is shown in FIG. 10. To prevent stringer formation, a single trench should not intersect multiple electrically isolated structures, as shown in FIG. 10. In addition, trenches should extend into a region 25 cleared during the second deep etch at each point where isolation is desired. A protrusion of a trench into a region 25 is termed a “nubbin” 23. By ensuring that every isolation trench 20 terminates in a region 25 cleared during the second deep etch (i.e. every trench ends with a nubbin), three faces of the trench are exposed to the second deep etch. Increased exposure to the second etch reduces incidence of stringers and results in the improved isolation characteristics of the device. Furthermore, trench fill materials attacked by the second deep etch may be selected, resulting in etching of the nubbins 23. Etching nubbins 23 to the sacrificial material 10 b ensures electrical isolation across the trench.
Because trenches 11 typically have a large height-to-width aspect-ratio, trenches may have keyholes 27 after filling, shown in FIG. 13. A keyhole is produced when the trench-fill material 12 plugs the top of a trench 11 before enough material may be deposited to completely fill the center region of the trench. Keyhole formation is undesirable because keyholes may significantly reduce the mechanical strength and reliability of the trench. When the trench-fill deposition is substantially isotropic (such as LPCVD silicon nitride) keyhole formation may be reduced using condyles 24, which are areas along the length of the trench with an increased trench width. Condyles reduce keyholing by enabling deposition material to travel down and laterally into the keyhole. FIG. 11 shows a plan and cross-sectional view of a trench and condyle before insulating material 12 is deposited. FIG. 12 shows the formation of lips 29 at the top of the trench which eventually pinch-off as shown in FIG. 13. Once the lips pinch-off further deposition of material inside the trench from the top is prevented. Since the cross-sectional area of the condyle is greater than the cross sectional area of the trench the condyle enables further deposition of material by lateral migration until the lips at the top of the condyle pinch-off, shown in FIG. 14. Examples of condyles 24 attached to trenches 20 are shown in FIG. 15. To prevent keyholes along the length of a trench, small regions of a trench may be chosen to have an increased width. Note that condyles may be formed at one or both ends of a trench, along the length of a trench including one or more ends, or along the length of a trench not including the ends, as illustrated in FIG. 15. Condyle shapes are not limited to the examples shown in FIG. 15; many shapes with an effective cross-sectional width greater than the nominal trench width may serve as a condyle.
In a further aspect of the invention, condyles may be placed at the end of nubbins 23. A perspective cut-away view of an isolation trench with a nubbin and a condyle is shown in FIG. 16. Alternatively, condyles may serve two functions: reduce keyholing while simultaneously serving as a nubbin. To serve these two functions, the boundary of the region removed during the second etch should stop along the length of the condyle such that at least part of the condyle protrudes into region 25.
As an example of a device fabricated in accordance with the present invention, FIG. 17 illustrates an accelerometer that measures translational acceleration. However, the principles of the invention are applicable to many other devices including, but not limited to gyroscopes, angular accelerometers, mechanical valves, and disk-drive head actuators.
An embodiment of an accelerometer comprises a proof-mass 21 c, stationary interdigitated comb fingers 21 f,g electronic circuitry 30 a, and electrical interconnect 31 a,b,c. The proof-mass 21 c is able to move relative to the substrate since sacrificial material underneath the proof-mass has been removed. The proof-mass includes a flexure 21 d that allows the proof-mass 21 c to deflect, and comb-fingers 21 e that are interleaved with stationary comb-fingers 21 f,g. Proof-mass comb-fingers 21 e form air-gap capacitors with stationary comb-fingers 21 f,g. Deflections of the proof-mass from translational accelerations along the input axis result in an imbalance in the air-gap capacitors. Electronic circuitry 30 a may measure this imbalance to determine acceleration. Furthermore, electronic circuitry 30 a may force-balance the proof-mass using electrostatic attraction between comb-fingers 21 e and 21 f,g or a separate set of comb-fingers.
The illustrated accelerometer built in substrate 10 includes the following: circuitry 30 a, interconnection 31 a,b,c and 32 c, as well as movable proof-mass 21 c. Mechanical elements such as the accelerometer proof-mass and the stationary, interdigitated comb fingers 21 f,g were formed during the second deep etch. The second deep etch removes substrate material thereby defining structural elements 21 c,d,e and 21 f,g. Many of the mechanical elements such as the proof-mass 21 c and the interdigitated comb-fingers 21 f,g are electrically isolated from the handle wafer by the removal of sacrificial material. Many of the mechanical elements such as the proof-mass 21 c and the stationary, interdigitated comb-fingers 21 f,g are electrically isolated from each other, the circuitry, and the remainder of the substrate by a combination of regions 25 formed during the second deep etch, and a set of filled isolation trenches 20 a,c with nubbins 23. Optional condyles may be added for improved trench filling. Electrical connection between the mechanical structures 21 and the associated circuitry 30 a is made using interconnection 31 a,b,c and contacts 32 c. The interconnection 31 a,b,c is formed from a conducting material that makes electrical connection to mechanical and electrical elements via contacts 32 c. Accelerometer performance is enhanced over prior-art implementations due to improved isolation provided by nubbins and increased mechanical strength of filled isolation trenches provided by condyles. When the interconnection material is metal a low-noise sensor may be produced since metal interconnect typically has a small sheet resistance.
FIG. 18, taken in conjunction with FIG. 19 shows yet another aspect of the invention. When circuits are integrated on the same substrate as a mechanical structure a set of geometric design rules typically specify minimum distances between the separation and/or overlap of certain layers with respect to each other. For example, when a typical CMOS process flow is integrated on the same substrate as a mechanical structure, a substrate contact may be used to attain connectivity from the circuits to the structure. In many cases, certain layers must be terminated in a specific order with specific critical dimensions for reasons that may include photolithographic, topological, or mask-alignment constraints. For illustrative purposes, if the process flow results in the deposition and patterning of a passivation layer 101, 111 on top of a layer of patterned metal 103, which is supported above the substrate by one or more dielectric layers 100, 110 a set of design rules may include DR1: metal to metal spacing of at least 2 microns, DR2: minimum metal width of at least 2 microns, DR3: minimum distance between metal and edge of dielectric of at least 3 microns, DR4: minimum distance between dielectric and edge of passivation of at least 3 microns, DR5: minimum distance between passivation and any structure formed by the second etch of at least 3 microns, DR6: minimum separation between contact and trench of at least 2 microns, DR7: contact width exactly 1 micron. For this illustrative example the minimum pitch for the fingers 106, 108 using the nubbin design of FIG. 18 is set by (2*DR6)+DR7, which equals 5 microns. FIG. 19 shows a layout of a similar structure that doesn't use nubbins. For similar design rules the minimum pitch between structures is given by 2*(DR3+DR4+DR5)+DR2 equaling 20 microns. The reduced pitch of the nubbin structure enables more active structural elements to be included in a given space than the method of FIG. 19 allows. Inclusion of more active structural elements can be used for attaining a more sensitive sensor, for example.
In an alternate embodiment of the invention, a dry-etch process may be used to remove the sacrificial layer 10 b beneath the structure 21. Referring to FIG. 6 and FIG. 20, a region 22 of the handle wafer 10 c, beneath a region under the structure 21, may first be etched to expose sacrificial material 10 b. Etch of the handle wafer may be anisotropic, using wet-etch processes such as KOH, TMAH, or EDP or dry-etch processes such as reactive ion etch. Furthermore, the crystal orientation of the handle wafer may be <111>, which will result in vertical sidewall etches in KOH, TMAH, or EDP. The handle wafer may also be isotropically etched using wet processes. Referring to FIG. 21, once sacrificial material 10 b is exposed, a dry-etch process (such as a plasma-based process) may be used to remove sacrificial material. Note that a dry-etch of sacrificial material 10 b to leave open areas 26 does not expose mechanical structures to potentially harmful wet processes. Furthermore, this method allows the trench-refill material 12 to be susceptible to etchants that attack the sacrificial material 10 b, such as a deposited silicon dioxide when the sacrificial material is silicon dioxide.
In yet another embodiment of the invention, the substrate material 10 a is doped single-crystal silicon and the trench-fill material 12 is doped polycrystalline silicon. The doping of the substrate and the trench-fill materials is selected such that a P-N semiconductor junction is created between the fill material and the substrate. For example, if the substrate has N-type dopant such as arsenic, the polycrystalline silicon would be doped with a P-type dopant such as boron. Due to diffusion of the polycrystalline silicon dopant into the substrate material 10 a, the P-N junction will typically occur in the substrate material. Electrical isolation may be provided with a reverse bias on the P-N junction formed between the trench 20 and the substrate 10 a. An advantage of this method is that the second deep etch attacks the trench material 20 at a rate similar to the substrate material 10 a. Consequently, nubbins 23 are substantially removed, reducing stringers. Thus, electrical isolation of the structural elements 21 is ensured.
The foregoing description, for the purposes of explanation, used specific nomenclature to provide a thorough understanding of the invention. However, it will be apparent to one skilled in the art that the specific details are not required in order to practice the invention. Thus, the foregoing descriptions of specific embodiments of the invention are presented for the purposes of illustration and description. They are not intended to be exhaustive or to limit the invention to the precise forms disclosed, obviously many modifications and variations are possible in view of the above teachings. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best utilize the invention and various embodiments with various modifications as are suited to the particular use contemplated.
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|U.S. Classification||257/622, 257/499|
|International Classification||G01P15/125, G01P15/08, B81B3/00|
|Cooperative Classification||G01P2015/0828, G01P2015/0814, B81B2201/0235, G01P15/0802, G01P15/125, B81C1/00246, B81C2203/0778, B81B2203/033|
|European Classification||G01P15/08A, G01P15/125, B81C1/00C12F|
|May 28, 1999||AS||Assignment|
Owner name: INTEGRATED MICRO INSTRUMENTS, INC., CALIFORNIA
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:CLARK, WILLIAM A.;JUNEAU, THOR N.;ROESSIG, ALLEN W.;AND OTHERS;REEL/FRAME:010014/0441
Effective date: 19990527
|Feb 21, 2001||AS||Assignment|
Owner name: INTEGRATED MICRO INSTRUMENTS, INC., CALIFORNIA
Free format text: MERGER;ASSIGNOR:INTEGRATED MICRO INSTRUMENTS, INC.;REEL/FRAME:011547/0629
Effective date: 20001215
|Jun 4, 2001||AS||Assignment|
Owner name: ANALOG DEVICES IMI, INC., CALIFORNIA
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:INTEGRATED MICRO INSTRUMENTS, INC.;REEL/FRAME:011859/0275
Effective date: 20010326
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